Are you looking for read ebook online? Search for your book and save it on your Kindle device, PC, phones or tablets. Download Rna Protein Interactions Of A Mitochondrial Group I Intron In Saccharomyces Cerevisiae PDF full book. Access full book title Rna Protein Interactions Of A Mitochondrial Group I Intron In Saccharomyces Cerevisiae.
| Author | : Hymavathi K. Tirupati |
| Publisher | : |
| Total Pages | : 298 |
| Release | : 1998 |
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| Author | : Daniel Michael Klass |
| Publisher | : |
| Total Pages | : |
| Release | : 2013 |
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We are on the threshold of a new era in our understanding of that fantastic feat of regulation at the core of life itself--gene expression. The rapid pace of new developments in genome-wide, high-throughput technologies has allowed us unprecedented access to observe multiple stages of the gene expression program for nearly the entire genome. This has revealed a widespread discordance between mRNA abundance and protein abundance for many genes whose expression changes in response to environmental stimuli, and a significant coordination of post-transcriptional regulation for specific sets of related mRNAs at the levels localization, translation, decay, and the noise in gene expression. Despite this evidence suggesting the existence of a coordinated regulatory framework that potentially affects the fate of every mRNA in the cell, our efforts to discern the underlying structure and regulatory themes are hindered by an incomplete understanding of RNA-protein interactions. To advance our comprehension of post-transcriptional regulation, we developed new tools to identify which proteins bind to RNA, which of those bind concurrently, which RNAs are bound by a given protein, and where each protein binds on each RNA. Using our proteomic tools we discovered hundreds unexpected RNA binding proteins, uncovered new RNA binding domains, identified widespread, concurrent binding with several RNA binding proteins, and inferred functional information from the simultaneous binding partners of several RNA binding proteins. We used our genomic, sequencing-based tools to systematically interrogate a large set of diverse RNA binding proteins and we discerned new themes from the resulting data. This revealed significant differences in function, localization, and regulation among the proteins encoded by the targets of a given RNA binding protein based on binding position. These results suggest that the functional consequences of the RBP-RNA interaction are determined not only by whether an mRNA is bound by an RBP but also by the position of the binding site within the mRNA and its relation to the other RBPs that bind the same mRNA. Overall, we found evidence of an extensive regulatory framework involving hundreds of RNA binding proteins, encompassing nearly the entire transcriptome, and extending our understanding of the RNA-protein interactions at the heart of post-transcriptional regulation.
| Author | : Stephanus Partono |
| Publisher | : |
| Total Pages | : 288 |
| Release | : 1989 |
| Genre | : Introns |
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| Author | : Nikoleta Georgieva Tsvetanova |
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| Total Pages | : |
| Release | : 2012 |
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The dynamic processes of a living cell depend on the coordinated temporal and spatial regulation of the many steps of gene expression. Transcription regulation is one control point of gene expression, and a gene can also be regulated post-transcriptionally, by RNA-binding proteins (RBPs). The biological significance of post-transcriptional regulation is especially evident in cases, where RBP binding controls the temporal precision of suppression and activation of important cellular stress responses. We developed a proteome-wide experimental approach for in vitro identification of novel RBPs and RNA-protein interactions in Saccharomyces cerevisiae. We found 12 novel RNA-binding proteins, the majority of which, surprisingly, are currently annotated as enzymes with roles in metabolic processes. We next used this proteomic approach to screen for proteins specifically interacting with the HAC1 RNA, which mediates activation of the yeast unfolded protein response (UPR). We found that HAC1 associated reproducibly with four small yeast GTPases, three of which are of the Ypt family of ras-GTPases. We further characterized one of them, the yeast Rab1 homolog Ypt1, and showed that Ypt1 interacted with unspliced HAC1 RNA only in the absence of ER stress. Selective Ypt1 depletion increased HAC1 RNA stability and expression, and also affected timely recovery from UPR. By developing and applying a novel proteomic approach for studying RNA-protein interactions, we established Ypt1 as an important regulator of HAC1 expression and UPR signaling. This unexpected protein-RNA interaction provides a biochemical mechanism for coordinating the key cellular processes of vesicle trafficking and ER homeostasis.
| Author | : Xing Li |
| Publisher | : |
| Total Pages | : 382 |
| Release | : 2004 |
| Genre | : Ribonucleases |
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| Author | : Robert Suran |
| Publisher | : |
| Total Pages | : 0 |
| Release | : 2010 |
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The group I introns from Tetrahymena thermophila, Tth.L1925, and Physarum polycephalum, Ppo.L1925, are closely related, sharing 70% sequence identity in their ribozyme regions. However, Ppo.L1925 also contains an open reading frame (ORF) encoding the homing endonuclease I-PpoI, which is separated from the ribozyme by a 53 nucleotide 3'UTR region; Tth.L1925 lacks both the ORF and 3'UTR regions. Previous studies of Ppo.L1925 have shown that the I-PpoI protein is translated from the RNA Pol I-derived spliced intron RNA. In order to better understand Ppo.L1925-encoded ORF translation, I created several chimeric ORF-containing Tth.L1925 introns and integrated them into the rDNA of Saccharomyces cerevisiae. Previous attempts to exchange the I-PpoI ORF found that small (~300 bp) ORFs can be integrated whereas larger ORFs disrupt intron splicing. I found that Tth.L1925based introns could accommodate and express both small and larger ORFs; these introns produce protein at levels similar to proteins produced from wild-type Ppo.L1925 (~ 0.01% of total yeast protein). To better understand the effect of intron sequence on protein expression, I added Ppo.L1925 sequences to chimeric Tth.L1925 introns. Some 3'UTR sequences had previously been shown to increase expression from Ppo.L1925 nearly 20-fold; however, all of the 3'UTR sequences tested in chimeric Tth.L1925 introns lowered expression. Replacing the Tth.L1925 5'end sequence with that of Ppo.L1925, though, increased expression nearly 10-fold. To further study the effect of the intron 5' end sequence on expression, I created an intron pool with random 5' end sequences. About 25% of these introns had increased expression up to 20-fold, while about 50% had their expression lowered to undetectable levels. I examined two models for expression of chimeric intron-encoded ORFs that explain how 5' end sequence changes could affect translation: interaction with the invasive growth IRES system and translation through formation of intron RNA circles. Addition of an invasive growth IRES sequence did not increase expression from a Tth.L1925-based intron, while RTPCR amplification of intron RNA circle junctions demonstrated no relationship between the circle species formed and expression level. These results suggest that the intron-encoded ORF is not being translated through either of these two models.
| Author | : Abby Lynn Shumaker Bifano |
| Publisher | : |
| Total Pages | : 177 |
| Release | : 2010 |
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| Author | : Huilin Li |
| Publisher | : |
| Total Pages | : 356 |
| Release | : 1998 |
| Genre | : Carrier proteins |
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| Author | : William S. Allison |
| Publisher | : |
| Total Pages | : |
| Release | : 2009 |
| Genre | : Active oxygen |
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| Author | : |
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| Total Pages | : |
| Release | : 2021 |
| Genre | : Gene expression |
| ISBN | : 9781071608340 |
